Radiological imaging apparatus

ABSTRACT

A radiological imaging apparatus allowing semiconductor radiation detectors to be easily replaced with new ones and densely arranged. Terminals ( 31   c   jk ) and ( 33   c   jk ) are provided on a bottom surface of a detector aggregate ( 40   mn ) including a plurality of semiconductor radiation detectors ( 1 ); the terminals is connected to electrodes ( 3  and  4 ) of the detectors ( 1 ). A plurality of zero insertion force connectors ( 56 ) are provided on a connecting device ( 33   jk ) installed on a support substrate ( 32   h ). The terminals ( 31   c   jk  and  33   c   jk ) are detachably attached to the zero insertion force connectors ( 56 ) to mount the detector aggregates ( 40   mn ) that are the semiconductor radiation detectors ( 1 ), on the support substrate ( 32   h ). When the detector aggregates ( 40   mn ) are attached to the zero insertion force connectors ( 56 ), since no frictional force acts on the terminals, the size of the gap between the detector aggregates ( 40   mn ) is reduced.

CROSS-REFERENCE TO RELATED APPLICATIONS

This application is a divisional of U.S. patent application Ser. No. 11/257,127, filed on Oct. 25, 2005, now U.S. Pat. No. 7,183,557 the subject matter of which is incorporated in its entirety by reference herein.

BACKGROUND OF THE INVENTION

The present invention relates to a radiological imaging apparatus, and in particular, to a radiological imaging apparatus using a semiconductor radiation detector.

In the prior art, a semiconductor radiation detector is electrically connected to wiring placed inside a support substrate using a method such as soldering, while being mechanically held on the support substrate (Third Edition of Radiation Measurement Handbook (NIKKAN KOGYO SHIMBUN LTD.), p. 559).

Conventionally, an operation of replacing a semiconductor radiation detector is not easy because of the need for a soldering process. On the other hand, the semiconductor radiation detector may use a connector that requires an insertion force to push a male terminal provided on the detector, in a spring of a female terminal. The female terminal is provided in the connector. Even a low insertion connector (LIF) requires a force of about several grams/pin to push the semiconductor radiation detector. The inventors have found that when the semiconductor radiation detector is pushed in the connector requiring an insertion force, a load on the semiconductor radiation detector exerts a strong frictional force between the male terminal on the semiconductor radiation detector and the spring of the female terminal, making the semiconductor radiation detector likely to incline. The inventors have also found that the inclining semiconductor radiation detector may slidably contact and damage a delicate semiconductor member of an adjacent semiconductor radiation detector. This problem may also occur when the semiconductor radiation detector is pulled out of its connector for replacement; also in this case, the adjacent semiconductor radiation detector may be damaged. This problem can be avoided by increasing the clearance between the semiconductor radiation detectors installed on the support substrate to the extent that the semiconductor member is not damaged by the contact. However, the formation of such a clearance causes the semiconductor radiation detectors to be more densely arranged. This prevents the further improvement of sensitivity and spatial resolution of the semiconductor radiation detector.

SUMMARY OF THE INVENTION

It is an object of the present invention to provide a radiological imaging apparatus that enables semiconductor radiation detectors to be more densely arranged.

To accomplish this object, the present invention is characterized that a plurality of semiconductor radiation detectors are detachably attached to a plurality of non-insertion connectors provided on a support substrate, a first electrode of each of the semiconductor radiation detectors is connected to a first wire provided in the support substrate via the corresponding zero insertion force connector, and a second electrode of the semiconductor radiation detector is connected to a second wire provided in the support substrate via the zero insertion force connector.

The semiconductor radiation detector is thus detachably attached to the zero insertion force connector. This substantially eliminates the need for a force for pushing the semiconductor radiation detector in the zero insertion force connector when the semiconductor radiation detector is inserted into the connector. This in turn reduces the degree of damage done to the semiconductor radiation detector by the semiconductor member of the adjacent one when the latter is inserted into the zero insertion force connector, even with a reduced clearance between the semiconductor radiation detectors. Therefore, it is possible to reduce the clearance between the semiconductor radiation detectors and to enable the semiconductor radiation detectors to be more densely arranged using the support substrate. The more dense arrangement of the semiconductor radiation detectors makes it possible to further improve the sensitivity and spatial resolution of each semiconductor radiation detector. The improvement of the detector sensitivity further reduces the time required for checks. Further, the application of the zero insertion force connectors allows the semiconductor radiation detector to be easily replaced with a new one.

Preferably, the first and second wires arranged in the support substrate have a matrix structure. This reduces the number of wires and the size of an area required to install the wires. This in turn increases the size of a free space in the support substrate in which the wires can be installed, thus contributing to increasing the density of arrangement of semiconductor radiation detectors. Further, the matrix structure of the wires enables a sharp reduction in the number of measuring circuits. This contributes to reducing the size of a detector head.

The present invention enables semiconductor radiation detectors to be more densely arranged while allowing each of the semiconductor radiation detectors to be replaced with a new one.

Other objects, features and advantages of the invention will become apparent from the following description of the embodiments of the invention taken in conjunction with the accompanying drawings.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a diagram showing the whole SPECT apparatus in accordance with a first embodiment of the present invention;

FIG. 2A is a detailed perspective view of a radiation detecting unit shown in FIG. 1, and FIG. 2B is a partly enlarged perspective view showing that part of the radiation detecting unit shown in FIG. 2A which is shown by arrow A;

FIG. 3 is an exploded perspective view of a detector aggregate shown in FIG. 2B;

FIG. 4A is a front view of the detector aggregate, FIG. 4B is a side view of the detector aggregate, and FIG. 4C is a side view of another embodiment of the detector aggregate;

FIG. 5A is a front view of the radiation detecting unit shown in FIG. 2B as viewed from the direction of an X axis in the figure, and FIG. 5B is a side view of the radiation detecting unit as viewed from the direction of a Y axis;

FIG. 6 is a top view of a connecting device shown in FIGS. 2A and 2B;

FIG. 7A is a sectional view partly showing a cross section of the connecting device shown in FIG. 6, the cross section being taken along line A-A, and FIG. 7B is a sectional view of the connecting device taken along line B-B in FIG. 6;

FIGS. 8A-8D are an enlarged sectional view of the internal configuration of the connecting device shown in FIGS. 2A and 2B, wherein FIG. 8A is an enlarged perspective view of a rotative movement member, FIG. 8B is an enlarged sectional view of that part of the connecting device shown in FIG. 7B which is shown by arrow D, the figure showing that holding of a detector is cancelled, FIG. 8C is an enlarged sectional view of a part of FIG. 7B shown by arrow E, the figure showing that the detector is held, and FIG. 8D is a view of a cross section passing through a notch; and

FIG. 9 is a conceptual drawing illustrating a wire matrix structure.

DESCRIPTION OF THE INVENTION

Embodiments of the present invention will be described below with reference to FIGS. 1 and 8A to 8D.

With reference to FIG. 1, description will be given of a single photon emission computer tomography apparatus (referred to as a SPECT apparatus below) that is an example of a semiconductor radiological imaging apparatus in accordance with an embodiment of the present invention. The SPECT apparatus 51 comprises a bed B that supports a patient P that is a subject, a pair of semiconductor radiation detecting devices (detector heads) 30, a rotating support 56, a data collecting and analyzing device 23, a data input device 24, and a display device 25. The semiconductor radiation detecting devices 30 are installed on the rotating support 56 so as to be offset from each other by 180° in a circumferential direction. The semiconductor radiation detecting devices 30 project from the rotating support 56 in a longitudinal direction of the bed B. The bed B is inserted between the two opposite semiconductor radiation detecting device 30. Each of the semiconductor radiation detecting devices 30 comprises a support member 6, a measuring circuit unit 8, a radiation detector unit 11, and a collimator 54 which are installed on the rotating support 56. The support member 6 is mounted on the rotating support 56 so as to be movable in a radial direction of the rotating support 56. The measuring circuit unit 8, radiation detector unit 11, and collimator 54 are mounted on the support member 6. Each radiation detector unit 11 faces toward the bed B. The collimator 54 is placed between the radiation detector unit 11 and the bed B to limit the view angles from semiconductor radiation detectors (referred to as detectors below) 1 of the radiation detecting unit 11. The radiation detecting unit 11, collimator 54, and measuring circuit unit 8 are housed in a light blocking electromagnetic shield 7 attached to the support member 6. The light blocking electromagnetic shield 7 blocks radiations emitted by an affected part C, that is, electromagnetic waves different from a γ ray 10. The light blocking electromagnetic shield 7 thus prevents the electromagnetic waves from affecting the radiation detecting unit 11 and the measuring circuit unit 8. Instead of the pair, three semiconductor radiation detecting devices 30 may be provided.

The bed B is moved on which the patient P to which a radioactive agent has been administered lies. The patient P is thus moved to between the pair of semiconductor radiation detecting devices 30. The γ ray 10 is emitted from the affected part C in the patient P in which the radioactive agent has been collected. The ray 10 is then incident on each of the detector 1 of the radiation detecting unit 11 through a through-hole portion in the collimator 54. The detector 1 outputs a γ ray detection signal (analog signal) to the measuring circuit unit 8, which then processes the signal. The data collecting and analyzing device 23 uses information output by the measuring circuit unit 8 to create a tomography information on the patient P. The data collecting and analyzing device 23 then displays the tomography information on the display device 25. The rotating support 56 is rotated to pivot the semiconductor radiation detecting device 30, including the radiation detecting unit 11, around the patient P. With the semiconductor radiation detecting device 30 pivoting, each detector 1 detects the γ ray 10 to output the γ ray detection signal. The following operations can be performed near the SPECT apparatus 51 using an operation panel 58: control of rotation of the rotating support 56, control of the distance between the radiation detecting unit 11 and the patient P, and control of position of the patient P using the bed. These operations can also be remotely performed using a data input device 24.

Now, with reference to FIGS. 2A and 2B, description will be given of the radiation detecting unit 11 used in the present embodiment.

The radiation detecting unit 11 comprises one mother board 31 that is a second support substrate, a plurality of (in the figure, five) daughter boards 32 _(h) (32 ₁, 32 ₂, . . . ) placed on the surface of the second support substrate that are first support substrates, and a plurality of detector aggregates 40 _(mn) that are detachably attached on each of the daughter boards 32 _(h) (see FIGS. 2B and 3). The width of the daughter board 32 _(h) is determined by the number of connecting devices 33 _(jk) that can be opened and closed by one rotation operating member (operation member) 36 as described later. If the semiconductor radiation detecting device 30 can be entirely operated from end to end using the single rotation operating member 36, the connecting device 33 _(jk) can be mounted directly on the mother board 31 without using the daughter board 32 _(h).

The daughter board 32 _(h) has the detector aggregate 40 _(mn) (see FIGS. 2B and 3) provided on its surface to detect the γ ray 10; a longitudinal direction of the detector aggregate 40 _(mn) is aligned with the direction (across the Y axis in the figure) in which the radiation detecting unit 11 is rotatively moved. The longitudinal direction of the detector aggregate 40 _(mn) is aligned with the rotatively moving direction of the radiation detecting unit 11 because this makes it possible to avoid the effect (vibration or the like) of an inertia force on the detector aggregate 40 _(mn) which is exerted as the rotation of the radiation detecting unit 11 is accelerated or decelerated, thus preventing electrodes from being bent. The daughter board 32 _(h) puts together faint analog signals provided by the detector aggregate 40 _(mn) upon detecting the γ ray 10. The daughter board 32 _(h) then outputs the resulting signal to the mother board 31. The detector aggregate 40 _(mn) is detachably mounted on the connecting device 33 _(jk), provided on a surface of the daughter board 32 _(h), as described later. As described later in detail, the detector aggregate 40 _(mn) is attached and removed by rotatively moving a head 36 a of the rotation operating member 36, exposed at an end of the daughter board 32 _(h).

Thus, in FIGS. 2A and 2B, five daughter boards 32 h (h=1 to 5) are provided on one mother board 31, and 2×10, that is, 20 connecting devices 33 _(jk) (j=1 to 10, k=1 or 2) are provided on the daughter board 32 _(h), and 16 (8×2) detector aggregates 40 _(mn)(m=1 to 8, n=1 or 2) are provided on the connecting device 33 _(jk). One detector aggregate 40 _(mn), has 16 detectors 1 as shown in FIG. 3, described below. One detector constitutes one pixel range. The numbers of components arranged shown above are only illustrative and may be increased or reduced depending on the purpose.

The detector aggregate 40 _(mn) will be specifically described with reference to FIGS. 3 and 4A to 4C.

The detector aggregate 40 _(mn) has two sub-aggregates 45A and 45B, conductive members (first conductive members) 41 _(s), (41 ₁, 41 ₂, 41 ₃, 41 ₄, 41 ₅, 41 ₆, 41 ₇, and 41 ₈) (S=1 to 8), and conductive members (second conductive members) 42 _(n) (42 ₁, and 42 ₂). Each of the sub-aggregates 45A and 45B has a plurality of anodes 46 _(A) (A=1 to 8) separately provided on one surface of a semiconductor base material (semiconductor member) 44 at predetermined intervals. Each of the sub-aggregates 45A and 45B has a plurality of cathodes 47 c (c=1 to 8) separately provided on the other surface of the semiconductor base material 44 at predetermined intervals. The anodes 46 _(A) and the cathodes 47 c are formed by depositing a conductive metal on the surface of the semiconductor base material 44. The semiconductor base material 44 is composed of cadmium telluride (CdTe) or the like, which generates charges when the γ ray 10 is incident on the semiconductor base material 44. The semiconductor base material 44 has a planar shape, and its longitudinal direction corresponds to the direction of the Y axis in the figure. Each of the anodes 46 _(A) lies opposite the corresponding cathode 47 c across the semiconductor base material 44. One detector 1 is composed of one anode 46 _(A), the cathode 47 c lying opposite this anode 46 _(A), and a part of the semiconductor base material 44, located between the anode 46 _(A) and the cathode 47 c. Each of the sub-aggregates 45A and 45B has substantially eight detectors 1, specifically, detectors 1A, 1B, 1C, 1D, 1E, 1F, 1G, and 1H. Each of the anodes 46 _(A) in the sub-aggregate 45A lies opposite the corresponding anode 46 _(A) in the sub-aggregate 45B. The plurality of conductive members 41 _(s), (41 ₁, 41 ₂, 41 ₃, 41 ₄, 41 ₅, 41 ₆, 41 ₇, and 41 ₈) are attached to each of eight anodes 46 _(A) in the sub-aggregate 45A using a conductive adhesive and also attached to each of eight anodes 46 _(A) in the sub-aggregate 45B using a conductive adhesive. Thus, the conductive member 41 _(s) is located between the anode 46 _(A) in the sub-aggregate 45A and the anode 46 _(A) in the sub-aggregate 45B. The two conductive members 42 _(n) (42 ₁ and 42 ₂) are attached separately to the eight cathodes 47 c in the sub-aggregate 45B and to the eight cathodes 47 c in the sub-aggregate 45B using a conductive adhesive. The conductive members 41 _(s) and 42 _(n) are composed of plates of conductive metal (for example, copper).

The detector aggregate 40 _(mn) is thus configured, so that one detector forms one pixel. That is, one detector aggregate 40 _(mn) provides 16 pixels.

As shown in FIGS. 3 and 4A, first terminals 43 _(s) (43 ₁, 43 ₂, 43 ₃, 43 ₄, 43 ₅, 43 ₆, 43 ₇, and 43 ₈) (s=1 to 8) project from the semiconductor base material 44 and extend from an end surface of the respective conductive members 41 _(s) along a Z axis. Second terminals 49 ₁ and 49 ₂ are similarly provided on an end surface of the conductive member 42 _(n) (42 ₁ and 42 ₂). Moreover, the second terminals 49 _(n) (49 ₁ and 49 ₂) have their roots folded so that their tips coincide with the arrangement of the first terminals 43 _(s), . . . of one detector aggregate 40 _(mn). Further, a large potential difference of several hundred V is present between the first terminals 43 ₁, . . . and the second terminal 49 ₁ or 49 ₂ in order to collect charges. Accordingly, the roots of the conductive members 42 ₁ and 42 ₂ are folded so as to create a gap between the conductive member and the semiconductor base material 44 of the detector aggregate 40 _(mn) to maintain electric insulation. As shown in FIG. 4B, all the first terminals 43 _(s) and second terminals 49 _(n) appear to be superimposed on one another as viewed from the side of the detector aggregate 40 _(mn).

The second terminal 49 ₁ and the first terminals 43 ₂ and 43 ₃ (43 ₆ and 43 ₇) have different poles. Accordingly, the second terminal 49 ₁ is separated from the first terminals 43 ₂ and 43 ₃ (43 ₆ and 43 ₇), arranged adjacent to the second terminal 49 ₁, as shown in FIG. 4A, in order to prevent sparks, increase insulation lifetime, and reduce a leakage current. This is to apply high voltages to these electrodes so that positive and negative charges generated by the semiconductor base material 44 upon detecting a radiation can migrate efficiently to the corresponding electrodes (anode 46 _(A) and cathode 47 c). The first terminals 43 ₁ and 43 ₈, which are located at the opposite ends of the detector aggregate 40 _(mn), are arranged so as to reduce the spacing between themselves so that a terminal insertion hole 34 _(mn) has a reduced opening area.

FIG. 4C is a side view showing another embodiment of the detector aggregate 40 _(mn). A terminal 43 _(s)′ is provided closer to the conductive member 42′₁ or 42′₂. This arrangement enables a detector holding member 38 shown in FIGS. 8A-8D, particularly the rotation operating member 36, to be located immediately below the detector aggregate 40 _(mn). This clarifies the positional relationship between the exposed part of the head 36 a of the rotation operating member 36, shown in FIGS. 8A-8D, and the corresponding detector aggregate 40 _(mn).

As shown in FIGS. 5A and 5B, output terminals 33 c _(jk) are provided on a surface of the daughter board 32 ₁ which is opposite the one on which the detector aggregate 40 _(mn) is placed; the output terminals 33 c _(jk) transmit a detected γ ray detection signal. The output terminals 33 c _(jk) are provided on a back surface of the daughter board 32 _(h) in association with each connecting device 33 _(jk).

Input terminals 31 c _(jk) are provided on a front surface of the mother board 31; the input terminals 31 c _(jk) are connected to the output terminals 33 c _(jk), and γ ray detection signals are input through the input terminals 31 c _(jk). The measuring circuit unit 8 (also see FIG. 1), provided on the back surface of the mother board 31 (which is opposite that surface on which the input terminals 31 c _(jk) are provided), has a function for converting the input γ ray detection signals into a digital signal and outputting the processed signals to the data collecting and analyzing device 23 (see FIG. 1).

The measuring circuit unit 8 is a custom ASIC (Application Specific Integrated Circuit) designed and manufactured on the basis of system specifications. The measuring circuit unit 8 is further divided into a measuring processing circuit and a control processing circuit. The measuring processing circuit first amplifies each of the input γ ray detection signal and measures a pulse height value. Then, the control processing circuit forms a digital signal by adding, to the pulse height value, a value (trigger information) measured when the γ ray detection signal is input and address information on the detector 1 (see FIG. 3) having provided the γ ray detection signal. The digital signal is then input to the data collecting and analyzing device 23. The address information on the detector 1 is obtained by identifying an X axis wire 96 _(s) and a Y axis signal read line 97 _(n), (see FIGS. 7A and 7B) through which the γ ray detection signal has been transmitted.

The connecting device 33 _(jk) will be described with reference to FIGS. 7A and 7B and 8A to 8D. In FIG. 6, the contours of the (in the figures, 8×2=16) detector aggregates 40 _(mn) mounted on the connecting device 33 _(jk) are shown by alternate long and two short dashes lines so that the arrangement of the detector aggregates 40 _(mn) can be understood. The connecting device 33 _(jk) has a plurality of zero insertion force connectors 52. As many zero insertion force connectors 52 as the detector aggregates 40 _(mn) are arranged in parallel in a housing 48 of the connecting device 33 _(jk); the detector aggregates 40 _(mn) are mounted on the connecting device 33 _(jk) in the direction of the X axis. Each of the zero force insertion connectors 52 has a pressure contact member 37 _(s) and a contact member 39 _(s), a pressure contact member 27 _(n) and a contact member 29 _(n), and one rotation operating member 36. There are 16 pressure contact members 37 _(s) and contact members 39 _(s), and 4 pressure contact members 27 _(n) and 4 contact members 39 _(n). The paired pressure contact member 37 _(s) and contact member 39 _(s) and the paired pressure contact member 27 _(n) and contact member 29 _(n) are installed in a bottom portion of the housing 48 (see FIGS. 7B and 8B). The paired pressure contact member 37 _(s) and contact member 39 _(s) lie opposite each other and the paired pressure contact member 27 _(n) and contact member 29 _(n) lie opposite each other. As many pairs of the pressure contact member 37 _(s) and contact member 39 _(s) as first terminals 43 _(s) are provided; the first terminals 43 _(s) are provided in the two detector aggregates 40 _(mn) arranged in series in the direction of the Y axis. As many pairs of the pressure contact member 27 _(n) and contact member 29 _(n) as second terminals 49 _(n) are provided; the second terminals 49 _(n) are provided in the two detector aggregates 40 _(mn) arranged in series in the direction of the Y axis. The paired contact members are arranged in a line along the longitudinal direction of the rotation operating member 36. The rotation operating member 36 is placed so as to extend in the direction of the Y axis. The opposite ends of the rotation operating member 36 are held by respective side walls (operation member support sections) of the housing 48. The operation member support sections support a detector support member 50 described later. One rotation operating member 36 is provided for the two detector aggregates 40 _(mn) arranged in series and is placed beside the pressure contact member 37 _(s). The pressure contact members 37 _(s) and 27 _(n) are composed of leaf springs.

The housing 48 has a plurality of terminal insertion holes 34 _(mn) formed inside and having openings in their front surfaces. The housing 48 has the detector support member 50 at its upper end in which the opening is formed and which supports a bottom surface of each detector aggregate 40 _(mn). The first terminal 43 _(s) and second terminal 49 _(n) (see FIGS. 3 and 4A) of each detector aggregate 40 _(mn) are inserted into the opening in the detector support member 50. Each detector aggregate 40 _(mn) is held by the detector support member 50 in the connecting device 33 _(jk). Two notches 35 formed in the opening of the terminal insertion hole 34 _(mn) avoid contacting the roots of the above-described second terminals 49 ₁ and 49 ₂ (see FIGS. 4A to 4C) with the detector support member 50. The notches 35 also position the held detector aggregate 40 _(mn).

The detector aggregate 40 _(mn) may have its surface provided with a thin insulating coating in order to prevent contact with another detector aggregate 40 _(mn).

As shown in FIGS. 7A and 7B, the conductive pressure contact member 37 _(s) is placed in the terminal insertion hole 34 _(mn) to elastically press the first terminal 43 _(s) to hold the detector aggregate 40 _(mn) and to lead the γ ray detection signal generated by the detection of γ ray 10 to the daughter board 32 _(h). The conductive pressure contact member 27 _(n) is also placed in the terminal insertion hole 34 _(mn) to elastically press the second terminal 42 _(n) to hold the detector aggregate 40 _(mn) and to lead the γ ray detection signal to the daughter board 32 _(h). The contact members 29 _(n) and 39 _(s) and rotation operating member 36 are also arranged in the terminal insertion hole 34 _(mn).

Pads 37 a _(s) and 37 c _(n) are provided on the connecting device 33 _(jk); the pad 37 a _(s) is formed at the terminal of the pressure contact member 37 _(s) and pad 37 c _(n)is formed at the terminal of the pressure contact member 27 _(n). Pads 32 a _(s) and 32 b _(n) are provided on the daughter board 32 _(h). The pad 37 a _(s) is connected, in a BGA (Ball Grid Array) manner, to a pad 32 a _(s) connected to a wire 96 _(s) located inside the daughter board 32 _(h). The γ ray detection signal led to the wire 96 _(s) via the pressure contact member 37 _(s) is output to the mother board 31 through the output terminal 33 c _(jk). The BGA connection is a solder connection based on a reflow process. The pad 37 c _(n) is connected, in the BGA manner, to a pad 32 b _(n) connected to a wire 97 _(n) inside the daughter board 32 _(h). The γ ray detection signal led to a wire 97 _(n) via the pressure contact member 27 _(n) is output to the mother board 31 through the output terminal 33 c _(jk).

The pad 37 a _(s) may be formed at the terminal of the contact member 39 _(s) rather than at the terminal of the pressure contact member 37 _(s) by extending the contact member 39 _(s) to the bottom surface of the housing 48. Similarly, the pad 37 c _(n) may be formed at the terminal of the contact member 29 _(n) rather than at the terminal of the pressure contact member 27 _(n) by extending the contact member 29 _(n) to the bottom surface of the housing 48.

As shown in FIG. 8A, the rotation operating member 36 has a head 36 a in which the tip of a removal tool 47 (see. FIG. 6) such as a driver is fitted, a body portion 36 b with an elliptical cross section, and a shaft 36 c rotatably supported by the connecting device 33 _(jk) (see FIG. 4). One rotation operating member 36 is provided for each terminal insertion hole 34 _(mn) (see FIG. 6). As shown in FIG. 7A, the rotation operating member 36 is rotatably supported by the housing 48 so that its longitudinal direction coincides with the longitudinal direction of the detector aggregate 40 _(mn). The rotation operating member 36, together with the pressure contact member 37 _(s), elastically presses a side surface of the first terminal 43 _(s) inserted into the terminal insertion hole 34 _(mn) toward the contact member 39 _(s). The rotation operating member 36, the pressure contact member 37 _(s), and the contact member 39 _(s) form the detector holding member 38 (see FIG. 8B) holding the detector aggregate 40 _(mn) across the first terminal 43 _(s). Further, the rotation operating member 36, together with the pressure contact member 27 _(n), elastically presses a side surface of the second terminal 49 _(n) inserted into the terminal insertion hole 34 _(mn) toward the contact member 29 _(n). The rotation operating member 36, the pressure contact member 27 _(n), and the contact member 29 _(n) form the detector holding member 28 (see FIG. 8D) holding the detector aggregate 40 _(mn) across the second terminal 49 _(n).

As shown in FIGS. 8B and 8C, the pressure contact member 37 s constitutes an elastically flexibly deformed cantilever. The pressure contact member 37 _(s) has a projection-like contact 37 b _(s) at its free end so that it can mechanically and electrically contact the first terminal 43 _(s). A projection-like contact 27 b _(n) is also provided at the tip of the pressure contact member 27 _(n).

With reference to FIGS. 6 and 8B, 8C, and 8D, description will be given of attachment of the detector aggregate 40 _(mn) to the detector holding members 38 and 28. Description will be given of installation of detector aggregates 40 ₈₁ and 40 ₈₂ in empty terminal insertion holes 34 ₈₁ and 34 ₈₂ as shown in FIGS. 4A to 4C. First, the removal tool 47 is used to rotatively move the rotation operating member 36 so that the longitudinal direction of cross section of the rotation operating member 36 coincides with the direction of the Z axis (see FIG. 8B). With the longitudinal direction of cross section of the rotation operating member 36 coinciding with the direction of the Z axis, the pressure contact member 37 _(s) of the detector holding member 38 does not contact the body portion 36 b of the rotation operating member 36. The width of a gap formed between the pressure contact member 37 _(s) and the contact member 39 _(s) is equal to or larger than the thickness of the first terminal 43 _(s) (the same as the thickness of the second terminal 49 _(n)). The width of a gap formed between the pressure contact member 27 _(n) and the contact member 29 _(n) is also equal to or larger than the thickness of the first terminal 43 _(s). Then, the first terminals 43 _(s) and second terminals 49 _(n) of the two detector aggregates 40 ₈₁ and 40 ₈₂ are simultaneously inserted into the openings of the terminal insertion holes 34 ₈₁ and 34 ₈₂. Each first terminal 43 _(s) is inserted between the corresponding pressure contact member 37 _(s) and contact member 39 _(s). Each second terminal 49 _(n) is inserted between the corresponding pressure contact member 27 _(n) and contact member 29 _(n). When the longitudinal direction of cross section of the rotation operating member 36 is parallel to the first terminals (or second terminals), each terminal can be inserted between the pressure contact member and the contact member without sliding the side surface of the terminal on the pressure contact member or contact member. Thus, each terminal is inserted between the pressure contact member and the contact member without any insertion force.

Then, the head 36 a (see FIG. 8A) of the rotation operating member 36 is rotated using the removal tool 47 through 90°. The longitudinal direction of cross section of the rotation operating member 3 is then orthogonal to the first terminals (or second terminals). The state in which the longitudinal direction of cross section of the rotation operating member 3 is orthogonal to the first terminals (or second terminals) includes the state in which the longitudinal direction is orthogonal to extensions of the first terminals (or second terminals). With the longitudinal direction of cross section of the rotation operating member 3 orthogonal to the first terminals, an outer surface of the body portion 36 b contacts a side surface of the pressure contact member 37 _(s) to press the pressure contact member 37 _(s) toward the contact member 39 _(s). The pressure contact member 37 _(s) is flexibly deformed (see FIG. 8C). The contact 37 b _(s) contacts a side surface of the first terminal 43 _(s) positioned between the pressure contact member 37s and the contact member 39 _(s). This makes the first terminal 43 _(s) and the pad 37 a _(s) electrically conductive to enable an analog signal provided by the detector aggregate 40 _(mn) to be output through the pad 37 a _(s). The contact 27 b _(s) contacts the second terminal 49 _(n) positioned between the pressure contact member 27 _(n) and the contact member 29 _(s) to make the second terminal 49 _(s) and the pad 37 c _(n) electrically conductive. The first terminal 43 _(s) and the second terminal 49 _(n) are pressed against the contact members 39 _(s) and 29 _(n) by the flexibly deformed pressure contact members 37 _(s) and 27 _(n). Thus, each detector 1 is attached to the zero insertion force connector 56 to mount the detector aggregates 40 ₈₁ and 40 ₈₂ on the connecting device 33 _(jk). That is, the detector aggregates 40 ₈₁ and 40 ₈₂ are mounted on the daughter board 32 _(h). The other detector aggregates 40 _(mn) are similarly mounted on the connecting device 33 _(jk). Owing to their high rigidity, the contact members 29 _(n) and 39 _(s) are not deformed even under the pressure of the pressure contact member.

With the detector aggregate 40 _(mn) attached to the zero insertion force connector 56, the anode 46 _(A), conductive member 41 _(s), cathode 47 _(c), and conductive member 42 _(n) of the detector aggregate 40 _(mn) are arranged perpendicularly to the daughter board 32 _(h). With all the detector aggregates 40 _(mn) attached to the respective zero insertion force connectors 56 of the connecting device 33 _(jk), the plurality of detectors 1 are arranged in a certain direction (for example, the X axis direction). A plurality of the detectors 1 are arranged in a different direction (for example, the Y axis direction) orthogonal to the above direction.

To remove the detector aggregate 40 _(mn) (40 ₈₁ and 40 ₈₂) from the connecting device 33 _(jk), the rotation operating member 36 is further rotated through 90° using the removal tool 47. Then, as shown in FIG. 8B, the pressure member 37 _(s) leaves the pressure contact member 37 _(s) to cancel the pressure of the contact 37 b _(s) on the first terminal 43 _(s). The pressure on the second terminal 49 _(n) is also cancelled. Thus, the detector 1, that is, the detector aggregate 40 _(mn) (40 ₈₁, 40 ₈₂) can be removed from the connecting device 33 _(jk), that is, the zero insertion force connector 52 without exerting a frictional force.

In the present embodiment, no thermal process (solder reflow or the like) is required in mounting the detector 1 on the daughter board 32 _(h). This enables the use of detectors 1 having characteristics impaired by heating history. The present embodiment is also significantly advantageous in that if detectors 1 are used which are not substantially affected by a single thermal process, a thermal process required to replace some defective detectors 1 does not fatigue surrounding detectors 1 even with heat cycles.

The first terminal 43 _(s) of the detector aggregate 40 _(mn) is inserted between the pressure contact member 37 _(s) and the contact member 39 _(s), which are open. The second terminal 42 _(n) of the detector aggregate 40 _(mn) is inserted between the pressure contact member 27 _(n) and the contact member 29 _(n), which are open. Then, the detector aggregate 40 _(mn) can be held on the detector support member 50. Accordingly, rotation of the rotation operating member 36 enables the detector aggregate 40 _(mn) to be easily attached to the zero insertion force connector 52. Naturally, the gap between the pressure contact member 37 _(s) and the contact member 39 _(s), which are open, is located immediately below the corresponding opening formed in the detector support member 50. The gap between the pressure contact member 27 _(n) and the contact member 29 _(n), which are open, is located immediately below the corresponding opening formed in the detector support member 50. Without the detector support member 50, the detector aggregate 40 _(mn) must be gripped using a certain method until the detector aggregate 40 _(mn) is attached to the zero insertion force connector 52 by rotating the rotation operating member 36.

In the above description, the detector holding member 38 allows the pressure contact member 37 _(s) and the rotation operating member 36 to cooperate in holding the detector aggregate 40 _(mn). However, the connecting device 33 _(jk) is not limited to such a configuration. Any structure can be used provided that it enables the detector 1 to be installed and removed without any insertion force (with zero frictional force).

Now, with reference to FIG. 9, description will be given of a structure for connecting the anodes 3 and cathodes 4 of a plurality of detectors 1 a arranged in a tetragonal lattice. The detector 1 a has the anode 3 and the cathode 4 on two surfaces of the semiconductor base material 44A so that the semiconductor base material 44A is sandwiched between the anode 3 and the cathode 4. The anode 3 and the cathode 4 are conductive metal plates. In each arrangement including the plurality of detectors 1 a arranged in the X axis direction, each of the anodes 3 is connected to a wire 12 extending in the X axis direction. In each arrangement including the plurality of detectors 1 arranged in the Y axis direction, each of the cathodes 4 is connected to a wire 14 extending in the Y axis direction.

In this manner, in the plurality of detectors 1 arranged like a plane, the plurality of detectors 1 connected together in one direction have their anodes 3 electrically connected together using one wire 12. Further, the plurality of detectors 1 connected together in a direction orthogonal to the above direction have their cathodes 4 electrically connected together using one wire 14. This wiring structure is called a matrix structure.

A γ ray is incident on one of the detectors 1, specifically the semiconductor base material 44, to generate charges through interaction. Then, information (γ ray detection signal) on the charges is obtained through the wires 12 and 14 connected to the detector 1. Simultaneity determination enables the identification of the wires 12 and 14 having simultaneously obtained the information on the charges. This makes it possible to determine that the γ ray has entered the detector 1 connected to the identified wires 12 and 14.

Now, with reference to FIGS. 7A and 7B, description will be given of a wire matrix structure in accordance with the present embodiment. In the present embodiment, wires 96 _(s) and 97 _(n) are provided in the daughter board 32 _(h) for each connector device 33 _(jk); the wire 96 _(s) extends in the X axis direction, the wire 97 _(n) extends in the Y axis direction, the wires 96 _(s) and 97 _(n) constitute the wire matrix structure shown in FIG. 9. In 16 detector aggregates 40 _(mn) mounted on one connecting device 33 _(jk), the common wire 96 _(s) electrically connects to the first terminals 43 _(s) (for example, the first terminals 43 ₁) of the detector aggregates 40 _(m1) adjacent to each other in the X axis direction as shown in FIGS. 7A and 7B. Separate wires 96 _(s) connect to the first terminals 43 ₂, 43 ₃, and the like of the detector aggregates 40 _(m1) adjacent to each other in the X axis direction. Further, the common wire 97 ₁ connects the second terminals 49 ₁ of the two detector aggregates 40 ₅₁ and 40 ₅₂, which are arranged in the Y axis direction.

The common wire 97 ₂ connects the second terminals 49 ₂ of the detector aggregates 40 ₅₁ and 40 ₅₂. Likewise, the common wire 97 _(n) connects the second terminals 49 _(n) of the two other detector aggregates 40 _(mn) arranged in the Y axis direction.

The wires 96 s and 97 n are connected to the measuring circuit unit 8 via the mother board 31. The measuring circuit unit 8 has a signal processing device (not shown) for each connecting device 33 _(jk). The signal processing device carries out a simultaneity determination on for one connecting device 33 _(jk) on the basis of charge information input to the wires 96 _(s) and 97 _(n). The measuring circuit unit 8 thus identify the wires 96 _(s) and 97 _(n) having simultaneously obtained the charge information. The detector 1 connected to the identified wires 96 _(s) and 97 _(n) has detected the γ ray 10. The signal processing device thus recognizes the position of the detector 1 having detected the γ ray 10.

The data collecting and analyzing device 23 creates tomography information on the patient P on the bases of the positional data on the detector 1 having detected the γ ray, the data having output by the corresponding signal processing device in the measuring circuit unit 8.

The present embodiment has the above wire matrix structure. Consequently, if for example, n×n detectors 1 are provided, the number of signal read channels connected to the detector 1 is sharply reduced to 2n. This makes it possible to reduce the size of detector pixels and to arrange the signal read channels behind the detector aggregate 40 _(mn). Further, the reduction in the number of signal read channels contributes to miniaturization of the semiconductor radiation detecting device 30.

Furthermore, a capacitive element (not shown) and a resistive element (not shown) using for wiring of the matrix structure are installed on the back surface of the daughter board (first support substrate) 32 _(h) and between the output terminals 33 c _(jk) (or on the front surface of the mother board and between the input terminals 31 c _(jk)); the capacitive element is positioned between the detector 1 and the measuring circuit unit 8 and connected to them, and the resistive element is positioned between the detector 1 and the high voltage power source and connected to them.

The above present embodiment can exert the advantages described below.

In the present embodiment, the terminals (first terminal 43 _(s) and second terminal 49 _(n)) connected to each electrode of the detector 1 can be detachably attached to the zero insertion force connector 52. The zero insertion force connector 52 enables the detector aggregate 40 _(mn), that is, the detector 1, to be easily replaced with a new one. The detector 1, that is, the detector aggregate 40 _(mn) that becomes defective in use is desirably replaced with a new one. By rotating the rotation operating member 36 to widen the gap between the pressure contact member and contact member of the zero insertion force connector 52 as shown in FIG. 8B, it is possible to easily pull the detector aggregate 40 _(mn) out of the zero insertion force connector 52 using, for example, vacuum tweezers. A new detector aggregate 40 _(mn) can also be easily attached to the connector 52. The replacement of the detector aggregate 40 _(mn) may be carried out with the daughter board 32 _(h) removed from the mother board 31.

According to the present embodiment, in FIG. 8B, when each terminal of the detector aggregate 40 _(mn) is inserted between the pressure contact member and contact member of the zero insertion force connector 52 using the vacuum tweezers, no frictional force is exerted between the terminal and the pressure contact member and contact member. That is, in inserting the detector 1 into the zero insertion force connector 52, it is unnecessary to exert a force for pushing the detector 1 in the connector. Further, no frictional force is exerted when each terminal of the detector aggregate 40 _(mn) is pulled out of the zero insertion force connector 52. Thus, when each terminal is inserted into and pulled out of the zero insertion force connector 52, the detector aggregate 40 _(mn) does not incline. This prevents the detector aggregate 40 _(mn) from contacting the end surface (that is not covered with the conductive member 42 _(n)) of the semiconductor base material 44 of the adjacent detector aggregate 40 _(mn). It is thus possible to prevent damage to the semiconductor base material 44 of the adjacent detector aggregate 40 _(mn), which has a low mechanical intensity. As described above, the detector aggregate 40 _(mn) does not incline when the terminal is inserted or pulled out. Accordingly, the clearance between the adjacent detector aggregates 40 _(mn) can be reduced taking electric insulation into account. The detector aggregates 40 _(mn), that is, the detectors 1, can be more densely arranged while preventing damage to the semiconductor base materials 44. This makes it possible to further improve the sensitivity and spatial resolution of the detector 1. The improvement of the detector sensitivity leads to a further reduction in the time required for checks. In the present embodiment, the application of the zero insertion force connector enables the detectors 1 to be densely arranged while allowing each detector aggregate 40 _(mn) to be replaced with a new one.

Further, the detector 1 can be connected to the daughter board 32 _(h) without any thermal process such as soldering. Consequently, the detectors 1, which are not resistant to high temperature, can be densely mounted.

In the present embodiment, the first terminal 43 _(s)and second terminal 49 _(n) included in the two sub-aggregates 45A and 45B are attached to the zero insertion force connector 52. This reduces the number of zero insertion force connectors 52 required, thus simplifying the structure of the semiconductor radiation detecting device 30.

The first terminal 43 _(s) and second terminal 49 _(n) of each of the plurality of detector aggregates 40 _(mn) are attached to one zero insertion force connector 52; the detector aggregates 40 _(mn) are arranged in series in a certain direction (the longitudinal direction of the rotation operating member 36 or the longitudinal direction of the semiconductor base material 44). This further reduces the number of zero insertion force connectors 52 required, thus further simplifying the structure of the semiconductor radiation detecting device 30.

According to the present embodiment, when the rotation operating member 36 is rotated, that is, operated, the detector aggregate 40 _(mn) can be held on the detector support member 50. This allows the detector aggregate 40 _(mn) to be easily attached to the zero insertion force connector 52.

In the present embodiment, the head 36 a, which is used for rotate the rotation operating member 36, is exposed from one end surface of the daughter board 32 _(h), that is, one surface of the housing 48. Thus, to perform an operation of rotating the rotation operating member 36, the head 36 a can be easily accessed by the removal tool 47.

In the present embodiment, the anode 46 _(A) and cathode 47 _(c) of the detector 1 are arranged perpendicularly to the daughter board 32 _(h). Accordingly, compared to a horizontal arrangement with respect to the daughter board 32 _(h), the perpendicular arrangement enables the detectors 1 to be densely located. This is because the perpendicular arrangement enables a reduction in the size of the gap between the adjacent detector aggregates 40 _(mn) which gap is required to arrange conductive members such as wires for connecting electrode films to wires provided in the support substrate.

Further, the conductive member 41 _(s) is used to connect the cathodes 47 _(s) of the two detectors 1 together, while the conductive member 41 _(s) is used to connect together the anodes 46 _(s) of the eight detectors 1 arranged in a row. The wire matrix structure is thus employed in the initial stage of wiring. This enables easy connecting operations. It is thus possible to quickly complete the wiring of the matrix structure in the daughter board 32 _(h), which is connected to the pads 37Aa_(s) and 37 c _(n) of the zero insertion force connector 52.

In the present embodiment, the first terminal 43 _(s) and second terminal 49 _(n) (see FIG. 3) of each of the detector aggregates 40 _(m1) and 40 _(m2) are attached to one set of the pressure contact member and contact member positioned close to one operating member 36; the detector aggregates 40 _(m1) and 40 _(m2) are arranged in series in the Y axis direction. However, the first terminal 43 _(s) of each of the detector aggregates 40 _(m1) and 40 _(m2) may be attached to a first set of the pressure contact member and contact member positioned close to one operating member 36. The second terminal 49 _(n) of each of the detector aggregates 40 _(m1) and 40 _(m2) may be attached to a second set of the pressure contact member and contact member positioned close to another operating member 36. The first and second sets are arranged in parallel. The pressure contact member and contact member of each set are installed in the bottom portion of the housing 48.

In the present embodiment, the detectors 1A, 1B, 1C, 1D, 1E, 1F, 1G, and 1H share the one elongate semiconductor base material 44. However, each of the detectors may comprise one semiconductor base material. In this case, the detectors 1A, 1B, 1C, 1D, 1E, 1F, 1G, and 1H are separated from one another. However, the detectors 1 are integrated by the conductive member 42.

In the present embodiment, as shown in FIG. 3, in the detector aggregate 40 _(mn), the detectors 1A, 1B, 1C, 1D, 1E, 1F, 1G, and 1H share one elongate semiconductor base material 33. However, each of the detectors 1A, 1B, 1C, 1D, 1E, 1F, 1G, and 1H may comprise one semiconductor base material. In this case, the detectors 1A, 1B, 1C, 1D, 1E, 1F, 1G, and 1H are separated from one another but are integrated together by the conductive member 42, attached to the cathode 47 _(c). The anodes 46 _(A) of the two sub-aggregates are connected together by the conductive member 41 _(s).

The above technical concept is applicable to the plurality of detectors 1 a arranged in the X axis direction as shown in FIG. 9. This arrangement should also be included in the scope of the present invention. The anode 3 shown in FIG. 9 is provided with a first terminal (not shown). The cathode 4 is provided with a second terminal (not shown). The above paired pressure contact member 37 _(s) and contact member 39 _(s) and paired pressure contact member 27 _(n) and contact member 29 _(n) are arranged in the X axis direction. The first and second terminals of a plurality of detectors 1 a arranged in the X axis direction are inserted between the pressure contact member and the contact member. Then, the rotation operating member 36 is rotated. This enables the first and second terminals of each detector 1 a to be attached to zero insertion force connector 52 without any insertion force. The detector 1 a can be mounted on the support substrate.

In FIG. 9, a plurality of the detectors 1 a arranged in the X axis direction may have their cathodes 4 integrated, with one second terminal attached to the integrated cathodes. In this case, a plurality of the first terminals and one second terminal of the plurality of detectors 1 a are attached to the one zero insertion force connector 52.

In the description of the present embodiment, the detectors are applied to the SPECT apparatus (Single Photon Emission CT apparatus) by way of example. However, the present invention is not limited to this. For example, the detectors may be applied to a PET (Positron Emission Tomography apparatus).

It should be further understood by those skilled in the art that although the foregoing description has been made on embodiments of the invention, the invention is not limited thereto and various changes and modifications may be made without departing from the spirit of the invention and the scope of the appended claims. 

1. A radiological imaging apparatus comprising: a plurality of semiconductor radiation detectors each having a semiconductor member, a first electrode attached to one surface of the semiconductor member, a second electrode attached to the other surface of the semiconductor member so as to sandwich the semiconductor member between the first electrode and the second electrode, and terminals connected to the electrodes of the semiconductor radiation detectors; a support substrate; and a plurality of connectors attached to the support substrate and to which said terminals are detachably attached, wherein each of the connectors has a plural pairs of contact members between which the terminal is inserted, and an operation member, when the operation member is brought into a first state, the terminal inserted between a pair of the contact members contacts the pair of contact members and is held by the pair of contact members, and when the operation member is brought into a second state, the terminal inserted between the pair of the contact members is brought out of contact with the contact members.
 2. The radiological imaging apparatus according to claim 1, further comprising a second support substrate on which a plurality of first support substrate that are the support substrate are mounted. 